KR20140121718A - In the form of a hybrid fuel cell electrode catalyst - Google Patents

Abstract

The present invention relates to an electrode catalyst for polymer electrolyte membrane fuel cells (PEMFCs). Provided are an electrode catalyst for a fuel cell which has two or more different kinds of carbon supports where a metallic catalyst material is supported, mixed therein; and a manufacturing method thereof. More specifically, provided are a hybrid electrode catalyst for a fuel cell where platinum (Pt) nanoparticles are supported on a carbon molecular sieve (CMS) and platinum-carbon black (Pt-CB) is mixed; and a manufacturing method thereof. The performance of a battery can be improved to approximately 200% maximally, and a highly efficient fuel cell can be provided via an economical method by reducing the amount of used platinum (Pt) when compared to a case solely using Pt-CB or Pt-CMS.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an electrode catalyst for a hybrid fuel cell,

The present invention relates to an electrode catalyst for polymer electrolyte membrane fuel cells (PEMFCs), and more particularly, to an electrode catalyst for a fuel cell in which two or more different carbon supports are mixed.

Proton exchange membrane fuel cells (PEMFCs) offer many advantages over other types of fuel cells (eg, low operating temperatures below 80 ° C, light weight, small volume, proper operation at high current density, Non-radiation, high efficiency) have attracted much attention as an alternative energy source. Despite the many advantages of PEMFC, there are some technical difficulties to break through to commercialization, and the main difficulty is high cost. One effective way to reduce costs is to reduce the amount of platinum used in the catalyst and increase the low utilization of the catalyst. Tsuchiya and Kobayashi reported that electrode costs account for 40% of all PEMFC costs, and most of the electrode cost is due to platinum. Recent studies have shown that by introducing nano-sized platinum particles (less than 10 nm) supported by small-sized carbon and by reducing the active layer, the active platinum reaction active sites are eventually increased to improve the utilization of platinum, It was proposed to reduce the platinum content.

There are two ways to solve these problems. One is to synthesize nano-sized platinum particles (3 nm or less), and the other is to use a carbon support having a specific surface area to ensure uniform spreading of the Pt nanoparticles. So far, carbon black (CB) has been most widely used as a catalyst support in PEMFC. The reason for this is that carbon black has high electrical conductivity. However, carbon black has limited surface dispersion due to its low specific surface area and platinum loss due to corrosion during abnormal operating conditions. Carbon nanotubes (CNTs) as a substitute for carbon black have received much attention due to their special structural / electrical properties. Recently, it has been reported that Pt (Pt / GNS) supported on graphene nanosheets is superior to Pt supported on commercial Vulcan XC-72 carbon black in methanol oxidation. Graphene has been known to exhibit excellent electrical conductivity. However, even with good conductivity, the redistribution phenomenon of each GNS (graphene nano sheet) was a problem and could not be used as an effective carbon support. This is because when the re-layering occurs, one side of the Pt / GNS is not used and the utilization of the Pt active point is reduced. Another alternative candidate for CB is a carbon molecular sieve (CMS), which has a high specific surface area, a relatively uniform pore size, an ordered pore size, An interconnected pore network, a graphitic wall, adjustable surface properties, and thermal / mechanical stability. On the other hand, recently, a Pt-CMS synthesized by a method of decomposing Pt (NH ₃ ) ^{2 +} ₄ -zeolite Y, which is a zeolite template method, at a different heating rate has been reported, and a Pt- It has been found that membrane electrolyte assemblies (MEA) exhibit better cell performance. This is because more electrochemically active sites are created by Pt nanoparticles that are uniformly distributed without aggregation. In this case, Pt (NH ₃ ) ²⁺ ₄ is first reduced to the zeolite Y template by ion exchange. However, since CMS has only micropores, there are some problems in terms of mass transfer. To overcome this problem, a high surface area and a uniform pore distribution are required.

At present, the hybrid type Pt / CB / Pt / CMS (hereinafter referred to as Pt / CBx / CMS100-x, where x is between 0 and 100 wt%) has high surface area and porosity due to CMS The material had not been used.

The inventors of the present invention completed the present invention by confirming the effect of adding Pt-CMS to Pt-CB in the course of electrocatalytic activity and cell polarization of a PEM fuel cell.

Korean Patent No. 10-0814840 (a cathode catalyst for a fuel cell, a method for producing the same, a membrane-electrode assembly for a fuel cell including the same, and a fuel cell system including the same) (Pt-carbon molecular sieve) and Pt-CMS as described in the present invention, and the like, as disclosed in Japanese Patent Application Laid- The hybrid type catalyst prepared by mixing a Pt-CB (Pt-carbon black) catalyst has not been disclosed at all.

The present inventors have found that Pt-carbon molecular sieve (Pt-CMS) or Pt-carbon black (Pt-CB) used as an electrode catalyst for polymer electrolyte membrane fuel cells (PEMFCs) ) Is used as a hybrid type fuel cell electrode in which platinum (Pt) nanoparticles are supported on a carbon molecular sieve (CMS) and platinum-carbon black (Pt-CB) The present inventors have completed the present invention by experimentally confirming that the catalyst exhibits a cell performance improvement of not less than about 200% at the maximum.

It is an object of the present invention to provide an electrode catalyst for a fuel cell in which two or more different kinds of carbon carriers are mixed.

It is another object of the present invention to provide a method of manufacturing an electrode catalyst for a fuel cell, wherein two or more different kinds of carbon carriers are mixed.

In order to accomplish the above object, the present invention provides an electrode catalyst for a fuel cell in which two or more different carbon supporting materials carrying a metal catalyst material are mixed.

Wherein the metal catalyst material comprises at least one metal selected from the group consisting of Pt, Pd, Ag, Cu, Ni, Co, Mo, Ru, Re, Rb, Pb and La and a metal oxide comprising the metal And Pt is preferably selected as a metal catalyst material.

The carbon carrier may be a carbon molecular sieve (CMS), carbon black (CB), graphite carbon, carbon nanotube, ordered porous carbon and carbon fiber and carbon fiber.

Meanwhile, it is preferable to mix a carbon molecular sieve (CMS) carrying platinum (Pt) and a carbon black (CB) carrying platinum (Pt) The carbon molecular sieve (CMS) may be contained in an amount of 1 to 50% by weight.

The present invention also provides a fuel cell including an electrode including the electrode catalyst for a fuel cell.

The present invention also provides a method for manufacturing a carbon nanotube, comprising: (1) carrying a metal catalyst material on a carbon carrier; (2) carrying a metal catalyst material on a carbon carrier different from the carbon carrier of the step (1); And (3) mixing the carbon carrier on which the metal catalyst material is formed by the steps (1) and (2).

Wherein the metal catalyst material comprises at least one metal selected from the group consisting of Pt, Pd, Ag, Cu, Ni, Co, Mo, Ru, Re, Rb, Pb and La and a metal oxide comprising the metal And at least one selected from the above.

The carbon carrier may be a carbon molecular sieve (CMS), carbon black (CB), graphite carbon, carbon nanotube, ordered porous carbon and carbon fiber and carbon fiber.

In step (1), platinum (Pt) is supported on a carbon molecular sieve (CMS), and in step (2), platinum Pt is supported on carbon black In step (3), the carbon molecular sieve (CMS) carrying the platinum (Pt) is preferably contained in an amount of 1 to 50% by weight.

According to the present invention, there is provided an electrode catalyst for a fuel cell in which two or more different kinds of carbon supports are supported, the metal catalyst material being supported on the electrode catalyst, and a method for manufacturing the electrode catalyst, that is, a carbon molecular sieve (CMS) (Pt-carbon black, Pt-CB) and a method for producing the same, and a method for producing the same, CB) or platinum-carbon molecular sieve (Pt-CMS) alone, it is possible to improve the performance of the battery at a maximum of about 200% or more. By reducing the amount of platinum (Pt) It is possible to provide a fuel cell with high efficiency by an economical method.

1 is a graph showing a carbon molecular sieve (CMS), a Pt-carbon molecular sieve (Pt-CMS), and a Pt-carbon black (Pt-CB) XRD pattern.
Figure 2 is a TEM image of a) Pt-CMS, b) Pt-CB using zeolite Y as template.
Figure 3 is a graph showing the BET isotherms of a) various Pt-CBx / CMS100-x (where x is 0-100%), and b) a graph showing the micropore size distribution.
4 is a graph showing the TG curves of a) Pt-CMS and Pt-CB, and b) a DTA curve of Pt-CMS and Pt-CB.
5 is a FT-IR spectrum graph of Pt-CB and b) an FT-IR spectrum graph of Pt-CMS.
6 is a graph showing the polarization curves of various MEAs processed with Pt-CB, Pt-CMS, Pt-CB25 / CMS75, Pt-CB50 / CMS50 and Pt-CB75 / CMS25.
7 is a graph showing cyclic voltammograms (CV) values of Pt-CB, Pt-CMS and various hybrid type catalysts.

The present invention provides an electrode catalyst for a fuel cell in which two or more different kinds of carbon carriers are supported.

Wherein the metal catalyst material comprises at least one metal selected from the group consisting of Pt, Pd, Ag, Cu, Ni, Co, Mo, Ru, Re, Rb, Pb and La and a metal oxide comprising the metal It may be at least one selected. However, as long as it can be used as a metal catalyst material, it can be used without limitation.

The carbon carrier may be a carbon molecular sieve (CMS), a carbon black (CB), a graphite carbon, a carbon nanotube, an ordered porous carbon, Carbon fiber, and the like. However, the present invention is not limited thereto.

Meanwhile, it is preferable to use a mixture of a carbon molecular sieve (CMS) carrying platinum (Pt) and a carbon black (CB) carrying platinum (Pt) The supported carbon molecular sieve (CMS) is preferably contained in an amount of 1 to 50% by weight.

Hereinafter, the present invention will be described in more detail with reference to Examples. It is to be understood by those skilled in the art that these embodiments are merely illustrative of the present invention and that the scope of the present invention is not construed as being limited by these embodiments.

Example 1. Synthesis of well-ordered microporous carbon bodies

A zeolite Y having a silicon (Si) / aluminum (Al) ratio of 5.1 was purchased from Zeolyst. The zeolite Y was heated to 120 DEG C and held in a vacuum oven for 8 hours to remove the gas. Perfluoroalcohol (FFA, 99% Acros) as a carbon precursor was charged into zeolite Y, cooled with ice water in a reduced pressure environment, placed in a nitrogen atmosphere at room temperature and held for 8 hours. After washing with mesitylene to remove FFA from the outer surface of the zeolite powder, the FFA inside the zeolite channel was heated at 80 ° C in nitrogen (N ₂ , 100 cc min ^-1 ) for 12 hours, And heated in nitrogen (N ₂ , 100 cc min ^-1 ) at 150 ° C. for 8 hours at 5 K min ^-1 . The resulting composite was placed in nitrogen (N ₂ , 100 cc min ^-1 ) and heated to 700 ° C at 5 K min ^-1 . When the temperature reached 700 DEG C, propylene gas (containing 2.0% in nitrogen gas) was passed through the reactor in a flow rate of 150 cc min ^-1 and maintained for 4 hours, followed by chemical vapor deposition (CVD) / Carbon composite was placed in nitrogen (N ₂ , 100 cc min ^-1 ) and heat treated at 900 ° C for 3 hours. Finally, the carbon bodies remaining as a result of dissolving the zeolite Y template with HF (47% aqueous solution) were washed several times with distilled water and dried overnight at 100 ° C. to form a carbon molecular sieve (CMS) .

Example 2. Preparation of Pt-carbon molecular sieve (Pt-CMS)

The Pt-CMS catalyst was prepared by the polyol method. This method dissolves H ₂ PtCl ₆ as a precursor salt in an ethylene glycol (EG) solution. 300 mg of CMS was dispersed in 180 ml of ethylene glycol and isopropyl alcohol (v / v = 4: 1) contained in a beaker, followed by ultrasonic treatment for 4 hours to form a uniform carbon ink solution. A predetermined amount of H ₂ PtCl ₆ was dissolved in 50 ml of the above ethylene glycol with stirring for 0.5 hour. Thereafter, the pH value of the ink solution prepared above was adjusted to 12 or more by adding dropwise 1 M NaOH solution. The solution is then allowed to stir at room temperature for 2 hours and then heated under reflux at 160 < 0 > C for 3 hours under nitrogen gas. The mixture was then stirred for 12 hours while cooling at room temperature. The resulting Pt-CMS particles in the resulting solution were filtered, washed with distilled water, and dried at 160 ° C for 1 hour. In the case of Pt-carbon black (Pt-CB), commercial Pt-CB (40% by weight of Pt) was used.

Example 3 Preparation of Hybrid Electrode and Membrane Electrode Assemblies (MEA) Using Pt-Carbon Black (Pt-CB) and Pt-Carbon Molecular Sieve (Pt-CMS)

In order to prepare two types of hybrid type catalysts, the amount of Pt-CMS is varied according to x in Pt / CBx / Pt / CMS100-x (x is 50 or 75 by weight ratio). The mixture was mixed with Pt-CB according to a predetermined amount of Pt-CMS, and an appropriate amount of distilled water was added thereto, followed by ultrasonic treatment at room temperature for 1 hour. After the ultrasonic treatment, it was dried at 60 캜 under vacuum overnight. The catalyst ink to be used for the cathode and the anode was made into an electrode processed in a hybrid form as follows. First, isopropyl alcohol (IPA, 99.5%, Samchun Chemical Co.) was added as a solvent, and 5 wt.% Of Nafion ^TM A dispersion medium (Dupont Chem. Co.) was added. In order to confirm whether it was mixed sufficiently, the catalyst ink was subjected to ultrasonic treatment for 30 minutes. Next, the catalyst ink was applied to a polymer electrolyte membrane (Nafion NRE-212, Dupont) at a density of 3 × 3 cm 2 Lt; / RTI > Thus, an anode and a cathode containing about 0.2 mg / cm 2 and 0.3 mg / cm 2 of Pt were obtained.

Experimental Example 1. Measurement of physical properties

(1) Identification of XRD patterns

Powder X-ray diffraction analysis (XRD, Rigaku Model D / Max 2200) using Cu Kα radiation was performed to obtain an XRD pattern for investigating the state of Pt nanoparticles.

The XRD patterns of CMS, Pt-CMS, and commercial Pt-CB are shown in Fig. The peaks near 6.7 in Figure 1 represent an array of regular, periodic fine holes resembling zeolite Y structures. 25.3 The nearest peak corresponds to the C of the graphitic carbon of the crystal structure. It is well known that graphitic carbon is more resistant to electrochemical oxidation and has better electrical conductivity than amorphous carbon. As can be seen from FIG. 1, the peak 111, peak 200, peak 220 and peak 311, which are characteristic peaks, are clearly visible, indicating that the Pt particles have been successfully formed. The sizes of Pt particles in Pt-CMS and Pt-CB were calculated to be 3.05 nm and 2.44 nm, respectively, using the Sherrer equation. Comparing the graphite peak of CMS to the graphite peak of CB, it was found that CMS was more graphitized than CB and showed better electrical conductivity.

(2) TEM image analysis of Pt-CMS, Pt-CB

At 40kV 30mA, the scan speed was 5 ㅀ min ^-1 and the resolution was 0.04 당 per 2 罐. A transmission electron microscope (TEM, 200 keV Carl Zeiss, EM 912 Omega) was taken to measure the particle size of Pt.

As described in the previous experimental procedure, the TEM image of the Pt-CMS and commercial Pt-CB prepared by the polyol method is shown in FIG. As shown in Figure 2, the particle size and pore size distribution of Pt nanoparticles on CB were narrower and smaller than those of Pt nanoparticles on CMS. The larger size of Pt particles in Pt-CMS may be due to the higher density of Pt nanoparticles on the surface of CMS, resulting in higher aggregation.

(3) N ₂ adsorption analysis

The BET (Brunauer-Emmett-Teller, Micrometrics, Tristar ™ II 3020) specific surface area for Pt-CB, Pt-CMS, Pt-CB75 / CMS25 and Pt-CB50 / Respectively.

To investigate the effect of Pt-CMS addition on Pt-CB, nitrogen adsorption analysis was performed. The results of the BET isotherm measurements of Pt-CB, Pt-CMS, Pt-CB25 / CMS75, Pt-CB50 / CMS50 and Pt-CB75 / CMS25 according to CMS content and micropore distribution are shown in FIG. The BET specific surface area increases with CMS content, Pt-CB is 151 m ² g ^-1 , Pt-CMS is 851 m ² g ^-1, Pt-CB25 / CMS75 is 501 m ² g ^-1, The Pt-CB50 / CMS50 ^{335 m 2 g -1, Pt-} CB75 / CMS25 showed 164 m ² g ^-1 value. This phenomenon appears to be due to the microporosity of the CMS as shown in Figure 3.b). As can be seen in FIG. 3, the higher the CMS content, the more fine pores of 3 nm or less.

(4) Thermogravimetric analysis (TGA)

Thermogravimetric analysis (TGA, Model TA2050 TA instruments) was performed to confirm the Pt content in the Pt-CMS, and the results are shown in FIG. As can be seen in Figure 4, in the case of CMS, the weight loss occurred at 170 ° C and 435 ° C, because weight reduction occurs due to combustion of carbon at each temperature at which amorphous carbon and graphitic carbon are burned Because. In Pt-CB, weight loss occurs at a lower temperature than Pt-CMS, which is due to irregular amorphous carbon structure, whereas Pt-CMS has a peak at 25.3 C (200) graphitic carbon peak of Figure 1 As you can see, it was more graphitized. The amount of Pt supported was 42% for CMS and 40% for CB.

(5) FT-IR spectrum analysis

Fourier transform infrared spectroscopy (FT-IR) was performed to confirm Pt-CMS and Pt-CB surface properties.

Figure 5 shows the FT-IR spectrum, where the spectral bands observed at 3400 cm ^-1 and 1631 cm ^-1 are due to adsorbed water molecules and the bending vibrations of the water molecules to CMS are due to immersion of hydroxyl functional groups For example, -OH), which allows Pt to be carried more in the CMS than in the CB. For CMS, the sharp band at 1740 cm ^-1 appears to be due to the carboxyl functionality, and the band observed at frequencies slightly lower than 3000 cm ^-1 is due to aliphatic functional groups such as CH ₃ and CH ₂ . At these locations, stronger bands of Pt-CMS than Pt-CB are observed, which may have resulted from the carbonization process.

Experimental Example 2. Measurement of electrochemical characteristics

Cyclic voltammetry (CV) analysis was performed on a conventional 3-pole electrochemical cell using a glassy carbon electrode (GCE). The glass carbon electrode was used as a working electrode with a diameter of 3 mm, a Pt wire as a counter electrode, and a saturated calomel electrode (SCE) as a reference electrode. Electrochemical analysis was recorded relative to a normal hydrogen electrode (NHE). Ink slurry negative electrode (cathode) was prepared by sonication ink slurry dropped the same amount of ink slurry of glass carbon electrode (GCE) on the diameter size 3㎜ area 0.0706cm ² with a micropipette, the Al ₂ O 1㎛ ₃ slurry. This finished electrode was used as a substrate for carbon-based catalysts. CV was measured using a potentiostat and a galvanostat at 25 ° C with 0.5 M sulfuric acid purged with nitrogen as the electrolyte solution (IM6, Zahner). The voltage was varied between 0.05V and 1.20V at a rate of 50mVs ^{-1 in} the form of a triangle wave, and the CV value was measured.

The electrochemically active surface area (ECSA) measurement of Pt-CB, Pt-CMS, Pt-CB75 / CMS25, Pt-CB50 / CMS50 and Pt-CB25 / CMS75 was carried out under cyclic voltammetry . The results are shown in FIG. 7, the peaks between 0.0 V and 0.3 V correspond to the peaks due to hydrogen adsorption / desorption, and the bilayer region between 0.3 V and 0.9 V is the region without adsorbed species, to be. The ECSA value of Pt-CB was 21.3 m ² g ^-1 , the ECSA value of Pt-CMS was 18.65 m ² g ^-1 , the ECSA value of Pt-CB75 / CMS ²⁵ was 20.36 m ² g ^-1 , The ECSA value of 22.65 m ² g ^-1 and the ECSA value of Pt-CB 25 / CMS 75 of 7.08 m ² g ^-1 were calculated by the following equations, respectively.

[Equation 1]

As shown in FIG. 6, the performance of various MEAs including the negative electrode and the positive electrode formed of Pt-CB, Pt-CMS, Pt-CB25 / CMS75, Pt-CB50 / CMS50 and Pt- The catalytic activities were compared. As a result, cell performance varied with CMS content. That is, when (H ₂ / O ₂ ) was used as fuel at 80 ° C and 1 atm, Pt-CB and Pt-CMS showed 315 mA at 0.6V. As the Pt-CMS content increased to 25% and subsequently increased to 50%, the current density increased to 892 mA and 1065 mA, respectively. This corresponds to 183% and 238% improvement over Pt-CB or Pt-CMS under the same experimental conditions. The improvement in cell performance by adding Pt-CMS to Pt-CB is because the mass transfer of the fuel is further enhanced and water molecules formed through the cathode reaction are removed by an appropriate amount of Pt-CMS micropores. On the other hand, if the Pt-CMS content is increased to 75% (for example, Pt-CB / CMS75, the current density is increased by 35% compared to only Pt-CB or Pt-CMS at 0.6 V, As shown in Figure 3b), the Pt-CB has a few micropores of less than 3 nm in diameter and the pores of more than 3 nm in size are particles of Pt-CB particles It appears as an interparticle pore. As the CB content with pores of 3 nm or greater decreases, the force of transferring water molecules is expected to eventually decrease because the liquid pressure gradient between the large pores of the Pt-CB and the small pores of the Pt-CMS becomes small. This increases the mass transfer resistance. Therefore, it seems that a proper amount of micropores is required for proper removal of water molecules from the anode while improving the mass transfer of the fuel. Too much micropores of less than 3 nm in the hybrid electrode make it difficult to transfer the fuel and remove the water molecules. It is well known that the rate of reaction at the cathode is slower than the rate at the anode. The improvement of the performance of the MEA using the hybrid type electrode according to the present invention may be attributed to an improvement in mass transfer when the amount of Pt-CMS mixed in the cathode is increased to a certain level. Therefore, it can be concluded that the structure of micropores is a very important factor in the performance of PEMFC fuel cell.

Example 3. Experimental Result

The following experimental results were obtained through the above-described experimental examples. A highly microporous carbon molecular sieve (CMS) was successfully synthesized, and platinum (Pt) of 3-4 nm in size was carried thereon. The amount of supported platinum was about 42%, which was similar to that of commercial Pt-CB. The surface of the CMS has a more hydrophilic property than that of the commercial Pt-CB, resulting in more platinum. From the results of the nitrogen adsorption isotherm measurements, the BET surface area increased with the CMS content. As a result of the test on the cell performance, it was found that the cell performance was greatly influenced by the pore structure of the carbon support. That is, if the content of Pt-CMS is too high (for example, 50% or more) in the Pt-CBx / CMS100-x hybrid composite electrode, the performance of the battery is rather reduced. This phenomenon is attributed to the fact that the micropores of the CMS are so large that they increase the mass transfer resistance, especially at high current densities. Cyclic voltametry analysis showed that cell performance was generally consistent with ECSA values, and that the presence of an adequate amount of microporous Pt-CMS improved cell performance.

Having described specific portions of the present invention in detail, it will be apparent to those skilled in the art that this specific description is only a preferred embodiment and that the scope of the present invention is not limited thereby. It will be obvious. Accordingly, the actual scope of the present invention will be defined by the appended claims and their equivalents.

Claims (12)

An electrode catalyst for a fuel cell in which two or more different kinds of carbon carriers carrying metal catalyst materials are mixed.
The method according to claim 1,
Wherein the metal catalyst material comprises at least one metal selected from the group consisting of Pt, Pd, Ag, Cu, Ni, Co, Mo, Ru, Re, Rb, Pb and La and a metal oxide comprising the metal And at least one selected from the group consisting of a metal oxide and a metal oxide.
The method according to claim 1,
The carbon carrier may be a carbon molecular sieve (CMS), carbon black (CB), graphite carbon, carbon nanotube, ordered porous carbon and carbon fiber and carbon fiber. The electrode catalyst for a fuel cell according to claim 1,

The method according to claim 1,
An electrode catalyst for a fuel cell, wherein a carbon molecular sieve (CMS) carrying platinum (Pt) and a carbon black (CB) carrying platinum (Pt) are mixed.
The method of claim 3,
The electrode catalyst for a fuel cell according to claim 1, wherein the carbon molecular sieve (CMS) containing Pt is contained in an amount of 1 to 50 wt%.
A fuel cell comprising an electrode including the electrode catalyst for a fuel cell according to any one of claims 1 to 5.
(1) carrying a metal catalyst material on a carbon carrier;
(2) carrying a metal catalyst material on a carbon carrier different from the carbon carrier of the step (1); And
(3) mixing the carbon carrier on which the metal catalyst material is formed by the steps (1) and (2).
8. The method of claim 7,
Wherein the metal catalyst material comprises at least one metal selected from the group consisting of Pt, Pd, Ag, Cu, Ni, Co, Mo, Ru, Re, Rb, Pb and La and a metal oxide comprising the metal Wherein the at least one selected from the group consisting of the at least one selected from the group consisting of alkaline earth metal and alkaline earth metal at least one selected from the group consisting
8. The method of claim 7,
The carbon carrier may be a carbon molecular sieve (CMS), carbon black (CB), graphite carbon, carbon nanotube, ordered porous carbon and carbon fiber and carbon fiber. The method for manufacturing an electrode catalyst for a fuel cell according to claim 1,
8. The method of claim 7,
Wherein the carbon carrier is a carbon molecular sieve (CMS) and the metal catalyst material is platinum (Pt) in the step (1).
8. The method of claim 7,
Wherein the carbon carrier is carbon black in step (2), and the metal catalyst material is platinum (Pt).
11. The method of claim 10,
The method for manufacturing an electrode catalyst for a fuel cell according to claim 1, wherein the carbon molecular sieve (CMS) containing Pt is contained in an amount of 1 to 50 wt%.

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